Formed where mantle erupts through crust
Answer:
The Hawaiian Islands were formed where mantle erupts through crust.
Explanation:
All the Hawaiian Islands were formed by the action of volcanoes that arose from the bottom of the sea, from a source of magma (hot spot).
Hawaii's hot spot theory holds that the tectonic plate under the Pacific moves, while the hot spot stands still, creating new volcanoes. For this reason, the volcanoes of the southern half of the island of Hawaii remain active today.
The oldest islands have inactive volcanoes, but in the newest ones volcanoes still active. The island of Hawaii has five volcanoes, and one of them is one of the most active in the world, the Kīlauea.
A 20kg tennis ball launcher shoots a 0.057kg tennis ball across a frictionless court. If the tennis ball's velocity after it is launched is 36m/s to the north , what is the velocity of the tennis ball launcher
Answer:
0.103 m/s to the south
Explanation:
The total momentum of the launcher+ball system must be conserved before and after the launch, so we can write:
[tex]p_i = p_f\\0 = m_L v_L + m_B v_B[/tex]
where
[tex]p_i =0[/tex] is the total initial momentum (before the launch)
[tex]m_L = 20 kg[/tex] is the mass of the launcher
[tex]v_L[/tex] is the velocity of the launcher after the launch
[tex]m_B = 0.057 kg[/tex] is the mass of the ball
[tex]v_B = +36 m/s[/tex] is the velocity of the ball after the launch (we take the north direction as positive)
Solving for [tex]v_L[/tex], we find
[tex]v_L = -\frac{m_B v_B}{m_L}=-\frac{(0.057 kg)(+36 m/s)}{20 kg}=-0.103 m/s[/tex]
and the negative sign means that the direction is south.
NEED HELP QUICKLY....A 9.0Ω resistor is connected in series with another resistor and a 6.0 V battery. The current in the circuit is 0.60 amps. Calculate the resistance of the unknown resistor. 9.0Ω 8.0Ω 5.0Ω 1.0Ω
Answer:
= 1.0 Ω
Explanation:
Total resistance of resistors is calculated by adding the resistance of each resistor.
In this case, one resistor is 9.0Ω and lets assume the other has R Ω
Therefore; Total resistance is = (9 + R) Ω
From the Ohm's law; R = V/I
Thus;
(9 + R) = 6.0/0.60
9 + R = 10
R = 1 Ω
Therefore, the resistance of the unknown resistor is 1.0 Ω
please help on this one?
Answer :D
Some characteristics shared by all electromagnetic waves are that they all travel at the same speed of light and their own transmission does not need medium. These wave types can also travel through empty spaces
It is D.They have the same speed
The rate at which charges move through a conductor is called
The electric current is the electric charge flow that travels through a material, which can be:
Solid (movement of electrons)
Liquid (movement of ions)
Gas (movement of ions or electrons)
Although in general, the movement of charges is taken as electrons.
In this sense, for electric current to exist, the electrons furthest from the nucleus of the atom of a material, will have to detach and circulate freely between the atoms of the body. Being the unit of this flow of current according to the International System of Units the Ampere (A).
As you move faster does the force of gravity increase or decrease?
Answer:
increase
Explanation:
think about it this way:
if you are falling from 2 different heights, 1- off a chair or 2- from a building
as you increase speed from the building you will have a harder impact, whereas when you fall of a chair your speed does not increase as much, even though itll still cause pain, ti wont be as much.
<3
I will mark brainlest! SO HELP ME M8!
1)
1. B
2. H
3. C
4. A
5. F
6. D
7. E
8. G
2) Perpendicular
3) Parallel
Make sure you study this
I'm up to modern physics this was a nice review for me
which is an example of velocity?
A. A pickup driving 30 km in 20 minutes
B. A car slowing down on a sharp curve
C. An airplane traveling 450 km/h
D. An 18 wheeler driving west at 50 km/h
PLZ help
BEST ANSWER WILL BE BRANLIEST!! 70 POINTS!!
13. The speed of light in a material is calculated by dividing the speed of light in a vacuum by the index of refraction in the material.
Calculate the speed of light in water which has a refraction rate of 1.33. Showing your work is not necessary.
14. The speed of light in a material is calculated by dividing the speed of light in a vacuum by the index of refraction in the material.
Calculate the speed of light in glass which has a refraction rate of 1.50
Showing your work is not necessary.
Answer:
Explanation:
The speed of light in a vacuum is approximately 3×10⁸ m/s.
In water with η=1.33:
v = (3×10⁸ m/s) / 1.33
v = 2.26×10⁸ m/s
In glass with η=1.50:
v = (3×10⁸ m/s) / 1.50
v = 2.00×10⁸ m/s
The speed of light in water with a refraction rate of 1.33 is approximately 2.26 x 10^8 m/s, while the speed of light in glass with a refraction rate of 1.50 is approximately 2.00 x 10^8 m/s.
Explanation:The formula to calculate the speed of light in a material is v = c/n, where v is the speed of light in the material, c is the speed of light in a vacuum, and n is the index of refraction of the material. In the first question, the index of refraction for water is given as 1.33. Plugging this value into the formula, we can calculate the speed of light in water by dividing the speed of light in a vacuum (approximately 3.00 x 10^8 m/s) by 1.33, which gives us a speed of light in water of approximately 2.26 x 10^8 m/s. In the second question, the index of refraction for glass is given as 1.50. Following the same calculation, we obtain a speed of light in glass of approximately 2.00 x 10^8 m/s.
Two displacement vectors have magnitudes of 5.0 m and 7.0 m, respectively. When these two vectors are added, the magnitude of the sum
A) is 12 m.
B) is larger than 12 m.
C) could be as small as 2.0 m, or as large as 12 m.
D) is 2.0 m.
Answer:
C) could be as small as 2.0 m, or as large as 12 m.
Explanation:
The magnitude of the vector given by the sum of the two vectors depends on the directions of the vectors.
In fact, we have two extreme conditions:
- when the two vectors have same directions, then the magnitude of their sum is equal to the sum of the magnitudes of the two vectors:
[tex]R=A+B=5.0 m + 7.0 m = 12.0 m[/tex]
- When the two vectors have opposite directions, the magnitude of their sum is equal to the difference between the magnitudes of the two vectors:
[tex]R=|A-B|=|5.0 m-7.0m|=2.0 m[/tex]
In all other intermediate cases, where the two vectors are neither parallel nor anti-parallel, the magnitude of the vector sum changes according to the components of the two vectors, and so it will span within this range of minimum length (2.0 m) and maximum length (12.0 m).
The magnitude of the resulting vector from the addition of two displacement vectors can range from a minimum value of their subtracted magnitudes to a maximum of their added magnitudes, depending on their alignment.
Explanation:When adding two vectors, the sum depends on their directions. If the vectors are in the same direction when added together, then their magnitudes will simply add up, which in this case gives us 12 m (5.0 m + 7.0 m). However, if the vectors are in opposite directions, we'd subtract the smaller magnitude from the larger. Here, that would be 7.0 m - 5.0 m, resulting in a magnitude of 2.0 m. So, the resultant displacement could range anywhere from 2.0 m (if completely opposite) to 12 m (if directly aligned).
Learn more about Vector Addition here:https://brainly.com/question/35874968
#SPJ3
Two speakers are wired to emit identical sounds in unison. The wavelength in air of the sounds is 6 m. Do the sounds interfere constructively or destructively at a point 10 m from both speakers?
Answer:
Costructively
Explanation:
The condition for constructive interference is:
[tex]|d_1 -d_2| = n \lambda[/tex] (1)
where
d1 is the distance of the point from the 1st source
d2 is the distance of the point from the 2nd source
n is an integer number
[tex]\lambda[/tex] is the wavelength of the wave (in this case, 6 meters)
In this problem, we are considering a point which is 10 m from both speakers, so we have:
[tex]d_1 = 10 m\\d_2 = 10 m\\d_1 - d_2 = 0[/tex]
And so eq.(1) is satisfied when n=0, which is an integer. Therefore, constructive interference occurs.
The sound waves from the two speakers, emitting in unison with a wavelength of 6 m, would neither interfere constructively nor destructively at a point 10 m from both speakers. This is because the distance of 10 m does not constitute an integral multiple of the wavelength or an odd multiple of half the wavelength.
Explanation:In this scenario, two speakers are emitting sounds with an identical wavelength of 6 m in unison. It is important to understand that whether sounds interfere constructively or destructively depends on their phase difference, which in turn is connected to the path lengths the sounds waves have traveled to reach the listening point. In this case, both sound waves are traveling the same distance (10 m) to reach the point in question.
As a principle, constructive interference occurs when the wave peaks (crests) or troughs coincide, which happens when the path difference is an integral multiple of the wavelength. On the other hand, destructive interference occurs when a wave peak coincides with a trough, and this happens when the path difference is an odd multiple of half the wavelength.
In this case, the distance from each speaker to the listening point is 10 m, which is not an integral multiple of the wavelength (6 m) or an odd multiple of half the wavelength (3 m). Therefore, neither perfectly constructive nor destructive interference would occur at a point 10 m from both speakers.
Learn more about Sound Wave Interference here:https://brainly.com/question/1287906
#SPJ3
Evan drew a diagram to illustrate radiation.
What do the arrows represent?
gases mixing with particles
liquid moving through a vacuum
moving particles
electromagnetic waves
Answer:
electromagnetic waves. (D)
Explanation:
I got it right on the test.
also the lines are electromagnetic waves (if that makes since)
hope this helps! :)
Electromagnetic induction is the production of a voltage across a conductor when it is exposed to a varying magnetic field. This process is essential in which of these technologies? A)Laser technolgy. B)electric motors. C) Automobile manufacturing. D) Electric power distribution.
Answer:
D) Electric power distribution.
Explanation:
Electric power distribution requires high voltages to efficiently transmit electric power. This requires use of a transformer which uses electromagnetic induction.
Answer:
D) Electric power distribution.
Explanation:
As we know that the Faraday's law of electromagnetic induction says that rate of change in magnetic flux linked with a closed conducting loop will induce EMF in the loop.
This induced EMF is used for power production so here when we use it for the production of voltage across conductor.
it is used in AC generator when a coil is rotated at high speed between strong magnetic field of magnets.
This is induced EMF is given by
[tex]EMF = NBA\omega sin(\omega t + \phi)[/tex]
so here correct answer will be
D) Electric power distribution.
what is the sl unit of pressure?
Answer:
The SI unit for pressure is Pascal (Pa) I believe :)
Mark brainliest if correct please!
To find acceleration, you first _______, then divide by time *
Determine distance
Determine time
Determine velocity
Determine acceleration
Answer:
the answer is d
Explanation:
Yeah answer is d bro
Two identical metal rods are heated in a fire. The first rod glows red, the second rod glows yellow. Which one is colder?
Red I believe ????????????????????????
As metal heats, the color gets lighter, so it would start off as red, then change to orange, then yellow then white.
Red is the colder color.
How do electric and magnetic fields interact in an electromagnetic wave?
Answer:
Electric and magnetic field waves are oriented at 90 degree angles relative to each other.
Explanation:
if are spaced closely together on the map,there is a drastic temperature change over the distance
Answer:
isotherms
Explanation:
If are spaced closely together on the map,there is a drastic temperature change over the distance called isotherms.
What are isotherms?The isotherms on a map show the areas with the same temperature levels. Isotherms are the lines that join the points of the same temperature on a map.
In other words, an isotherm of a specific temperature level passes through areas that reflect the temperature identical to the temperature of the isotherm. The functioning of the isotherm lines is similar to that of contour lines. Isotherm lines prove beneficial in the determination of relative temperature variations and other meteorological applications.
An isothermal process has a constant temperature. As a result, the internal energy is constant and there has been no change in it at all. Since there are no intermolecular forces or particle interactions in an ideal gas by definition, a change in pressure at constant temperature does not affect on the internal energy.
Therefore, If are spaced closely together on the map,there is a drastic temperature change over the distance called isotherms.
Learn more about temperature on:
https://brainly.com/question/11464844
#SPJ5
In a particular experiment to study the photoelectric effect, the frequency of the incident light and the temperature of the metal are held constant. Assuming that the light incident on the metal surface causes electrons to be ejected from the metal, what happens if the intensity of the incident light is increased? Check all that apply. The choices are:
a. The work function of the metal decreases.
b. The number of electrons emitted from the metal per second increases.
c. The maximum speed of the emitted electrons increases. The stopping potential increases.
Part B: In another experiment, the intensity of the incident light and the temperature of the metal are held constant. Assuming that the initial light incident on the metal surface causes electrons to be ejected from the metal, what happens if the frequency of the incident light is increased?
1. b. The number of electrons emitted from the metal per second increases.
In the photoelectric effect, when light is shone on a metallic surface, the photons of the light give energy to the electrons in the metal. Electrons can then be emitted by the surface if they receive enough energy, according to the equation:
[tex]hf=\phi + K[/tex] (1)
where
(hf) is the energy given by the photon, with h being the Planck constant and f the frequency of the photon
[tex]\phi[/tex] is the work function of the metal, which is the minimum energy required to extract an electron from the metal
K is the maximum kinetic energy of the electron
Keep in mind that in the photoelectric effect, 1 photon hits 1 electron only. Now let's analyze the 3 statements:
a. The work function of the metal decreases. --> FALSE. In fact, the work function of the metal depends only on the properties of the metal itself, so it is not affected by the intensity of the incident light.
b. The number of electrons emitted from the metal per second increases. --> TRUE. When the light intensity is increased, more photons are shone on the metal, so more photons hit more electrons, and so more electrons in the metal are emitted.
c. The maximum speed of the emitted electrons increases. The stopping potential increases. --> FALSE. As we see from the equation (1), the maximum kinetic energy of the electrons depends only on the frequency of the incident photon (f), not on the number of photons: therefore, the maximum speed is also not affected by the intensity of the light, and the stopping potential is not affected neither (the stopping potential is equal to the minimum potential necessary to prevent the photoelectrons from escaping the metal)
2) c. The maximum speed of the emitted electrons increases. The stopping potential increases.
In this case, the frequency of the incident light is increased: this means that the incident photons have more energy, therefore they give more energy to the electrons, therefore the electrons will be emitted with larger maximum speed. As a consequence, the stopping potential will also be larger, since a larger potential will be needed to stop the photoelectrons. So the only correct statement is c.
The other 2 statements are wrong because:
a. The work function of the metal decreases. --> FALSE. In fact, the work function of the metal depends only on the properties of the metal itself, so it is not affected by the intensity of the incident light.
b. The number of electrons emitted from the metal per second increases. --> FALSE. This depends only on the intensity of the light (number of photons emitted), which in this case does not change.
When the intensity of the incident light is increased, the number of electrons emitted from the metal per second increases.
What is photoelectric effect?The term potoelectric effect refers to the fact that electrons are emitted from the surface of a metal when irraditaed with light of appropriate frequency.
We know that when the frequency of the incident light is increased, the kinetic energy of the emitted electrons is increased. Again,When the intensity of the incident light is increased, the number of electrons emitted from the metal per second increases.
Learn more about photoelectric effect: https://brainly.com/question/1190311
in which direction does the magnetic field in the center of the coil point?
A.Left
B.Up
C.Down
D.Right
The direction does the magnetic field in the center of the coil point as shown in the diagram is the left.
The standard right hand grip rule can be used to know the direction of the magnetic field.
The rule states that If the right hand fingers curl round the coil in the direction of the current, then the thumb points in the direction of the magnetic field down the centre of the coil.
It is known that at the centre of the circular loop, The magnetic field lines are straight. The various segment of circular loop carrying current create magnetic field lines in the same direction with in the loop.
Conclusively, The direction of magnetic field at the centre of circular coil is simply known to be perpendicular to the place of the coil.
Learn more from
https://brainly.com/question/12505019
The direction of the magnetic field in the center of a coil depends on the direction of the current flowing through the coil.
Explanation:The direction of the magnetic field in the center of a coil depends on the direction of the current flowing through the coil. According to the right-hand rule, if the current flows clockwise in the coil when viewed from the top, the magnetic field points downward in the center of the coil. Conversely, if the current flows counterclockwise, the magnetic field points upward in the center of the coil. Based on this, the correct option would be C. Down.
Learn more about Magnetic field in the center of a coil here:https://brainly.com/question/33812728
#SPJ2
A 525 kg satellite is in a circular orbit at an altitude of 575 km above the Earth's surface. Because of air friction, the satellite eventually falls to the Earth's surface, where it hits the ground with a speed of 1.90 km/s. How much energy was transformed into internal energy by means of air friction? 14457750000 Incorrect: Your answer is incorrect.%20orbit%20at%20an%20altitude%20of%20575%20km%20above%20the%20Earth's%20surface.%20Because%20of%20air%20friction%2C%20the%20satellite%20eventually%20falls%20to%20the%20Earth's%20surface%2C%20where%20it%20hits%20the%20ground%20with%20a%20speed%20of%201.90%20km%2Fs.%20How%20much%20energy%20was%20transformed%20into%20internal%20energy%20by%20means%20of%20air%20friction%3F%20%20%20%20J/study?trackid=ae7684c4b7d0&strackid=e93f14d66685&event=enter_submit#p=1
Answer:
[tex]1.69\cdot 10^{10}J[/tex]
Explanation:
The total energy of the satellite when it is still in orbit is given by the formula
[tex]E=-G\frac{mM}{2r}[/tex]
where
G is the gravitational constant
m = 525 kg is the mass of the satellite
[tex]M=5.98\cdot 10^{24}kg[/tex] is the Earth's mass
r is the distance of the satellite from the Earth's center, so it is the sum of the Earth's radius and the altitude of the satellite:
[tex]r=R+h=6370 km +575 km=6945 km=6.95\cdot 10^6 m[/tex]
So the initial total energy is
[tex]E_i=-(6.67\cdot 10^{-11})\frac{(525 kg)(5.98\cdot 10^{24} kg)}{2(6.95\cdot 10^6 m)}=-1.51\cdot 10^{10}J[/tex]
When the satellite hits the ground, it is now on Earth's surface, so
[tex]r=R=6370 km=6.37\cdot 10^6 m[/tex]
so its gravitational potential energy is
[tex]U = -G\frac{mM}{r}=-(6.67\cdot 10^{-11})\frac{(525 kg)(5.98\cdot 10^{24}kg)}{6.37\cdot 10^6 m}=-3.29\cdot 10^{10} J[/tex]
And since it hits the ground with speed
[tex]v=1.90 km/s = 1900 m/s[/tex]
it also has kinetic energy:
[tex]K=\frac{1}{2}mv^2=\frac{1}{2}(525 kg)(1900 m/s)^2=9.48\cdot 10^8 J[/tex]
So the total energy when the satellite hits the ground is
[tex]E_f = U+K=-3.29\cdot 10^{10}J+9.48\cdot 10^8 J=-3.20\cdot 10^{10} J[/tex]
So the energy transformed into internal energy due to air friction is the difference between the total initial energy and the total final energy of the satellite:
[tex]\Delta E=E_i-E_f=-1.51\cdot 10^{10} J-(-3.20\cdot 10^{10} J)=1.69\cdot 10^{10}J[/tex]
A photoelectric effect experiment finds a stopping potential of 1.93 V when light of wavelength 200 nm is used to illuminate the cathode.a.) what metal is the cathode made?b.) what is the stopping potential if the intensity of light is doubled?
a) Zinc (work function: 4.3 eV)
The equation for the photoelectric effect is:
[tex]E=\phi + K[/tex] (1)
where
[tex]E=\frac{hc}{\lambda}[/tex] is the energy of the incident photon, with
h = Planck constant
c = speed of light
[tex]\lambda[/tex] = wavelength
[tex]\phi[/tex] = work function of the metal
K = maximum kinetic energy of the photoelectrons emitted
The stopping potential (V) is the potential needed to stop the photoelectrons with maximum kinetic energy: so, the corresponding electric potential energy must be equal to the maximum kinetic energy,
[tex]eV=K[/tex]
So we can rewrite (1) as
[tex]E=\phi + eV[/tex]
where we have:
[tex]\lambda=200 nm = 2\cdot 10^{-7} m[/tex]
V = 1.93 V
e is the electron charge
First of all, let's find the energy of the incident photon:
[tex]E=\frac{hc}{\lambda}=\frac{(6.63\cdot 10^{-34}Js)(3\cdot 10^8 m/s)}{2\cdot 10^{-7}m}=9.95\cdot 10^{-19} J[/tex]
Converting into electronvolts,
[tex]E=\frac{9.95\cdot 10^{-19}J}{1.6\cdot 10^{-19} J/eV}=6.22 eV[/tex]
And now we can solve eq.(1) to find the work function of the metal:
[tex]\phi = E-eV=6.22 eV-1.93 eV=4.29 eV[/tex]
so, the metal is most likely zinc, which has a work function of 4.3 eV.
b) The stopping potential is still 1.93 V
Explanation:
The intensity of the incident light is proportional to the number of photons hitting the surface of the metal. However, the energy of the photons depends only on their frequency, so it does not depend on the intensity of the light. This means that the term E in eq.(1) does not change.
Moreover, the work function of the metal is also constant, since it depends only on the properties of the material: so [tex]\phi[/tex] is also constant in the equation. As a result, the term (eV) must also be constant, and therefore V, the stopping potential, is constant as well.
The velocity acquired by a body moving with uniform acceleration is 12 m/s in 2 s and 18 m/s in 4 s. Find the initial velocity of the body.
Answer:
6 m/s
Explanation:
At constant acceleration, the final velocity is equal to the initial velocity plus the product of time and acceleration:
v = at + v₀
We know that at t=2, v=12. And at t=4, v=18.
12 = 2a + v₀
18 = 4a + v₀
We can solve the system of equations for v₀. If we double the first equation:
24 = 4a + 2v₀
And subtract the second:
24-18 = 4a-4a + 2v₀ - v₀
6 = v₀
The initial velocity is 6 m/s.
Electrons are made to flow in a wire when there is
A) an imbalance of charges in the wire.
B) more potential energy at one end of the wire than the other.
C) a potential difference across its ends.
Answer:
C) a potential difference across its ends.
Explanation:
We know , according to Ohm's law, at a constant temperature, current flows through a circuit is directly proportional to the voltage applied.
[tex]V=I\times R[/tex] Here R is resistance provide by circuit.
[tex]I=\dfrac{V}{R}.[/tex]
Also, currents flows in the opposite direction of electrons. If current flows then only electron flows.
From Ohm's law , current flows only when their is a potential difference.
Therefore, same goes with electrons as they flow only when current flows electrons.
C) Option is correct.
Electrons will flow in a wire when there is a potential difference (voltage) across its ends (C) or an imbalance of charges in the wire (A). This flow creates a current. Similar to water in a pipe, electrons move from areas of high potential energy to areas of low potential energy.
Explanation:Electrons flow in a wire when there is a potential difference across its ends. This potential difference, commonly known as voltage, it is kind of like the 'push' that gets the electrons moving. It's like sending a sled down a hill, the top of the hill has more potential energy, the 'push', than the bottom of the hill. It's similar with electrons and voltage. If there's more voltage at one end of the wire than the other - hence, a potential difference - the electrons will 'slide' down this 'hill', creating a current.
Another way to think about it is water in a pipe. The water (electrons) will flow from a place of high potential energy to a place of low potential energy. So, if there's a higher potential (voltage) at one end of the wire than the other, the electrons will flow to equalize the energy.
An imbalance of charges in the wire can also lead to electron flow, as electrons move from areas of high concentration (negatively charged) to areas of lower concentration.
Learn more about Electron Flow here:https://brainly.com/question/32334961
#SPJ6
A spring in a pogo-stick is compressed 12 cm when a 40. kg girl stands on the stick. what is the force constant for the pogo-stick spring?
Final answer:
The force constant of the pogo-stick spring is 3266.67 N/m.
Explanation:
The force constant of a spring can be found using Hooke's Law, which states that the force exerted by a spring is directly proportional to its displacement. The formula to calculate the force constant is: k = F / x, where k is the force constant, F is the force exerted by the spring, and x is the displacement of the spring. In this case, the force exerted by the spring is the weight of the girl standing on the pogo stick, which can be calculated using the formula:
F = mg, where m is the mass of the girl and g is the acceleration due to gravity.
Plugging in the values:
F = (40 kg) * (9.8 m/s²) = 392 N
Substituting the values into the formula for the force constant:
k = (392 N) / (0.12 m) = 3266.67 N/m
This chart shows characteristics of three different waves all with the same wavelength of 10 m but moving at different frequencies
Answer:
the answer is B
Explanation:
wave x has the highest hertz making it the answer
Microwave ovens emit microwave energy with a wavelength of 12.1 cm. What is the energy of exactly one photon of this microwave radiation?
Answer:
[tex]1.64\cdot 10^{-24}J[/tex]
Explanation:
The energy of a photon is given by:
[tex]E=\frac{hc}{\lambda}[/tex]
where
[tex]h=6.63\cdot 10^{-34} Js[/tex] is the Planck constant
[tex]c=3\cdot 10^8 m/s[/tex] is the speed of light
[tex]\lambda[/tex] is the wavelenght of the photon
For the microwave photons in this problem,
[tex]\lambda=12.1 cm=0.121 m[/tex]
so their energy is
[tex]E=\frac{(6.63\cdot 10^{-34}Js)(3\cdot 10^8 m/s)}{0.121 m}=1.64\cdot 10^{-24}J[/tex]
The energy of a microwave photon can be calculated using the Planck-Einstein relation, with the microwave's frequency derived from its given wavelength. Microwaves are electromagnetic radiation with wavelengths longer than infrared but shorter than radio waves, used in applications such as microwave ovens.
Explanation:To determine the energy of a microwave photon, we need to use the Planck-Einstein relation, which states that the energy of a photon is directly proportional to its frequency and inversely proportional to its wavelength. This relation is given by the equation E=hv where E is the energy, h is Planck's constant and v is frequency.
The frequency v can be determined from the given microwave wavelength 12.1cm using the equation v=c/λ, where c is the speed of light and λ is the wavelength. Since the speed of light and Planck's constant are known quantities, by substituting these values into the Planck-Einstein relation, we can find the energy of a single photon.
It's crucial to note that microwaves, a form of electromagnetic radiation, have longer wavelengths compared to infrared but shorter than radio waves. The energy level they possess makes them suitable for applications such as microwave ovens, where they cause water molecules to rotate faster, resulting in food heating up.
Learn more about Microwave photon energy here:https://brainly.com/question/2088247
#SPJ3
Two musicians are comparing their trombones. The first produces a tone that is known to be 438 Hz. When the two trombones play together they produce 6 beats every 2 seconds. Which statement is true about the second trombone?
a.It is producing a 444-Hz sound, and could be producing no other sound frequency.
b.It is producing either a 436-Hz sound or a 440-Hz sound.
c.It is producing either a 435-Hz sound or a 441-Hz sound.
d.It is producing either a 432-Hz sound or a 444-Hz sound.
e.It is producing a 441-Hz sound, and could be producing no other sound frequency.
Answer:
c.It is producing either a 435-Hz sound or a 441-Hz sound
Explanation:
Beat is a phenomenon of interference that occurs when two waves with slightly different frequency interfere with each other. When this occurs, the frequency of the beats is given by
[tex]f_B = |f_1 -f_2|[/tex] (1)
where f1, f2 are the frequencies of the two waves.
In this problem, we have 6 beats every 2 seconds, so the beat frequency is
[tex]f_B = \frac{6}{2 s}=3 Hz[/tex]
We also know the frequency of one of the two sounds,
[tex]f_1 = 438 Hz[/tex]
So according to eq.(1), this means that the sound of the second trombone can have 2 different frequencies:
[tex]f_2 ' = f_1 + f_B = 438 Hz + 3 Hz = 441 Hz\\f_2 '' = f_1 - f_B = 438 Hz - 3 Hz = 435 Hz[/tex]
What is the average speed for a car driving a distance of 186 meters to the north in a time of 28 seconds?
a
6.64m/s
b
9.15m/s
c
3.64m/s
d
7.64m/s
e
9.64m/s
Answer:
6.642857143 or a . 6.64 m/s
Explanation:
186/28 = 6.642857143
A beta and gamma source, Co-60, was placed in a chamber which was first lined with paper and then, after, with copper and lead. A Geiger counter was used in both cases to detect the emission of radiation. You expect
Answer:
Paper will not stop any radiation.
Copper will stop beta radiation.
Lead will damp the gamma radiation
Explanation:
A Geiger counter is an instrument used to measure the radiation level. There are majorly three types of radiation: Alpha, beta and gamma. Alpha radiations have least energy and gamma radiation have the highest energy. Alpha radiation can be stopped even by a sheet of paper. Beta radiation can be stopped using a sheet of aluminum or copper. To stop the gamma radiation you need lead. Also, the energy of the gamma radiation and thickness of the lead shield will decide how much of the gamma radiation is stopped by the lead sheet.
In the given scenario, when only paper is used neither beta nor gamma radiation will be stopped and Geiger counter will show you the high radiation level. When the source is lined with copper and lead, beta radiation will be stopped and gamma radiation will be damped. So Geiger counter will show reduced level of radiation.
Answer:the answer is d
Explanation:
What happens to temperature during condensation?
CONDENSATION is the process by which water vapor (gas) in the atmosphere turns into water (liquid state). It is the opposite of EVAPORATION.Cool temperatures are essential for condensation to happen, because as long as the temperature in the atmosphere is high, it can hold the water vapor and delay condensation. So the temperature in condensation rises.